Cooling assembly for engine

ABSTRACT

To make it possible to extract air from a water pump without the need for a dedicated structure for air extraction in the water pump which supplies cooling water to a cooling jacket on a cylinder head or cylinder block of a horizontally opposed or V-type engine. A circular pump chamber for rotatably housing an impeller inside a pump housing of a water pump includes an upper discharge path extending diagonally upwards and connecting to an upper end section of the pump chamber, and a lower discharge path extending diagonally downwards and connecting to a lower end section of the pump chamber. First and second connecting pipes respectively extending in a straight line along a line extended from the upper and lower discharge paths have inner ends communicating with the upper and lower discharge paths, and outer ends forming first and second discharge ports.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a cooling assembly for an engine, for supplying cooling water from a single water pump to a cooling jacket that is provided on the cylinder head or cylinder block of a horizontally opposed or V-type engine.

2. Description of Related Art

A cooling assembly of the related art is known, for example, in Japanese Patent laid-open No. Hei. 10-103060.

In the above-described cooling assembly of the related art, an upper discharge path communicating with an upper end of a pump chamber, and a lower discharge path communicating with a lower end of the pump chamber are provided inside a pump housing. A pair of discharge ports at outer ends of the upper and lower discharge paths are connected to left and right cooling jackets. It is possible to supply cooling water to the pair of left and right cooling jackets using a single water pump. However, the upper and lower discharge paths are formed in a whirlpool shape, and a discharge port formed by an outer opening of the upper discharge path is located below an upper end of the pump chamber, while a discharge port formed by an outer opening of the lower discharge path is located above a lower end of the pump chamber. This means that air may become trapped in an upper part of the inside of the pump chamber, and in order to remove the air from inside the pump chamber it is necessary to provide an air extraction hole or the like.

SUMMARY OF THE INVENTION

The present invention has been conceived in order to solve this problem, and an object of the present invention is to provide a cooling assembly for an engine that makes it possible to easily extract air from the water pump without the need for a dedicated structure for air intake.

In order to achieve the above object, a first aspect of the present invention provides a cooling assembly for an engine, the engine having first and second cylinder blocks with respective cylinder bores extending in a direction orthogonal to an axis of a crankshaft arranged at right angles to the axis of the crankshaft, a first cooling jacket provided on the first cylinder block and a first cylinder head connected to the first cylinder block, a second cooling jacket provided on the second cylinder block and a second cylinder head connected to the second cylinder block, and first and second discharge ports provided with a single water pump respectively independently connected to the first and second cooling jackets, the cooling assembly comprising a circular pump chamber for rotatably housing an impeller inside a pump housing of a water pump arranged between the two cooling jackets at a position below the lowest part of the first and second cooling jackets, an upper discharge path extending diagonally upwards and connecting to an upper end section of the pump chamber, and a lower discharge path extending diagonally downwards and connecting to a lower end section of the pump chamber, wherein first and second connecting pipes respectively extending in a straight line along a line extended from the upper and lower discharge paths have inner ends communicating with the upper and lower discharge paths, and outer ends stretching to a pump housing as first and second discharge ports.

With this structure, in the water pump for supplying cooling water to the first and second cooling jackets, a passage from the upper end of the pump chamber through the upper discharge path and leading to the first discharge port at the outer end of the first connecting pipe extends diagonally so that the first discharge port is at the highest position, while another passage from the lower end of the pump chamber through the lower discharge path and leading to the second discharge port at the outer end of the second connecting pipe extends diagonally so that the lower end of the pump chamber is at the highest position. This means that there is no section where air will become trapped at any point from the second discharge port through the lower discharge path, pump chamber and upper discharge path to the first discharge path. Therefore, there is no need for a dedicated air extracting structure such as an air extraction bolt etc. Furthermore, it is easy to extract air from the water pump.

According to a second aspect of the present invention, in addition to the first aspect, first and second inlet pipes are respectively connected between the first discharge port and the first cooling jacket, and between the second discharge port and the second cooling jacket. Furthermore, the length of the first inlet pipe is shorter than the length of the second inlet pipe by a distance causing a flow resistance corresponding to a difference in height between the first and second discharge ports on the second inlet pipe side. With this structure, a balance is struck between a difference in height between the first and second discharge ports of the water pump and a flow resistance generated in the first and second inlet pipes. Furthermore, it is possible to supply cooling water in a uniform manner to the first and second cooling jackets from a common water pump.

Further scope of applicability of the present invention will become apparent from the detailed description given hereinafter. However, it should be understood that the detailed description and specific examples, while indicating preferred embodiments of the invention, are given by way of illustration only, since various changes and modifications within the spirit and scope of the invention will become apparent to those skilled in the art from this detailed description.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will become more fully understood from the detailed description given hereinbelow and the accompanying drawings which are given by way of illustration only, and thus are not limitative of the present invention, and wherein:

FIG. 1 is a side elevation of a motorcycle;

FIG. 2 is an expanded cross sectional drawing along line 2—2 in FIG. 1;

FIG. 3 is a cross sectional drawing along line 3—3 in FIG. 2;

FIG. 4 is an expanded view of essential parts of FIG. 2;

FIG. 5 is a cross sectional drawing along line 5—5 in FIG. 3;

FIG. 6 is a cross sectional drawing along line 6—6 in FIG. 3;

FIG. 7 is an expanded sectional view of a cylinder block running along line 7—7 in FIG. 3;

FIG. 8 is a drawing in the direction of arrow 8 in FIG. 2;

FIG. 9 is an expanded sectional view of a cylinder head running along line 9—9 in FIG. 3;

FIG. 10 is a cross sectional drawing along line 10—10 in FIG. 9;

FIG. 11 is an expanded cross sectional drawing along line 11—11 in FIG. 2;

FIG. 12 is a cross sectional drawing along line 12—12 in FIG. 11; and

FIG. 13 is an expanded view of essential parts of FIG. 3.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Hereinafter, one embodiment of the present invention will be described with reference to the accompanying drawings. Referring first to FIG. 1, there is shown a low floor type or easy-rider style motorcycle on which a power unit P composed of a horizontally-opposed type two-cylinder/four-cycle engine E and a transmission M is mounted.

A body frame F includes a pair of right and left main frames 11 extending downwardly, rearwardly from the front side of the motorcycle in the running direction of the motorcycle. A steering handle 13 is steerably supported by a head pipe 12 commonly provided at the front ends of a pair of the main frames 11. A front wheel WF is suspended from a front fork 14 turnable together with the steering handle 13.

The rear ends of both of the main frames 11 are connected to a transmission case 15 of the transmission M of the power unit P. The transmission case 15 constitutes a part of the body frame F.

Front ends of a pair of right and left rear frames 16 extending to the rear side of the motorcycle are connected to the transmission case 15. The front end of a rear fork 17 is vertically swingably connected to the transmission case 15. A rear wheel W, is rotatably supported by the rear end of the rear fork 17. A cushion unit 18 is provided between a rear portion of the rear fork 17 and each of the rear frames 16. A drive shaft (not shown) for transmitting the output of the transmission M to the rear wheel WR is contained in the rear fork 17. The drive shaft is connected to an output member of the transmission M via a universal joint.

The entire body frame F is covered with a body cover 20 made from a synthetic resin. A tunnel portion 20 a for covering the power unit P is formed at an intermediate portion of the body cover 20 in the longitudinal direction. A seat 21 on which a driver is to be seated is provided on the body cover 20 at a position behind the tunnel portion 20 a, and steps 20 b on which the driver is to rest her/his foot are provided on the right and left sides of the tunnel portion 20 a. A fuel tank 22 is mounted on the rear frames 16 in such a manner as to be located under the seat 21 and to be covered by the body cover 20. An air cleaner 23 is mounted on the main frames 11 in such a manner as to be located above the engine E. A pair of right and left radiators 24 are mounted on the main frames 11 between the air cleaner 23 and the engine E. The air cleaner 23 and the radiators 24 are also covered by the body cover 20, and openings (not shown) through which running wind is introduced to the air cleaner 23 and the radiators 24 are formed in the front end portion of the body cover 20.

Referring to FIGS. 2 and 3, a main body of the engine E includes a first cylinder block 25 ₁ disposed on the right side when the motorcycle is directed forwardly in the running direction; a second cylinder block 25 ₂ disposed on the left side when the motorcycle is directed forwardly in the running direction; a crank case 26 commonly connected to the cylinder blocks 25 ₁ and 25 ₂; a first cylinder head 27 ₁ connected to the first cylinder block 25 ₁ on a side opposite to the crank case 26; and a second cylinder head 27 ₂ connected to the second cylinder block 25 ₂ on the opposed side to the crank case 26.

The crank case 26 is formed by connecting a front case half 26 a on the front side in the longitudinal direction of the motorcycle to a rear case half 26 b on the rear side in the longitudinal direction of the motorcycle. A crank shaft 28 having a substantially horizontal axial line in the longitudinal direction of the motorcycle is rotatably supported by the crank case 26. First and second cylinder bores 29 ₁ and 29 ₂, which extend in opposite directions from each other at 180° with respect to the axial line of the crank shaft 28, are provided in the first and second cylinder blocks 25 ₁ and 25 ₂ in such a manner that the axial lines of the cylinder bores 29 ₁ and 29 ₂ are directed substantially in the horizontal direction.

A piston 31 ₁, which forms a combustion chamber 30 ₁ between the first cylinder head 27 ₁ and the same, is slidably fitted in the first cylinder bore 29 ₁. A piston 31 ₂, which forms a combustion chamber 30 ₂ between the second cylinder head 27 ₂ and the same, is slidably fitted in the second cylinder bore 29 ₂. Both of the pistons 31 ₁ and 31 ₂ are commonly connected to the crank shaft 28 via connecting rods 32 ₁ and 32 ₂, respectively. The first and second cylinder blocks 25 ₁ and 25 ₂ are connected to the crank case 26 in such a manner that the axial line of the first cylinder bore 29 ₁ is offset by an offset amount L₁ from the axial line of the cylinder bore 29 ₂ onto one side in the axial direction of the crank shaft 28, more specifically, on the front side in the longitudinal direction of the motor cycle in this embodiment.

An intake port 33 ₁ (or 33 ₂) in communication with the combustion chamber 30 ₁ (or 30 ₂) is opened in an upper surface portion of the first cylinder head 27 ₁ (or second cylinder head 27 ₂). An exhaust port 34 ₁ (or 34 ₂) in communication with the combustion chamber 30 ₁, (or 30 ₂) is opened in a lower surface portion of the cylinder head 27 ₁ (or 27 ₂).

Referring particularly to FIG. 4, the first cylinder head 27 ₁ has an intake valve 35 ₁ for opening/closing the intake port 33 ₁ in communication with the combustion chamber 30 ₁ thereby taking air in the combustion chamber 30 ₁, and an exhaust valve 36 ₁ for opening/closing the exhaust port 34 ₁ in communication with the combustion chamber 30 ₁ thereby exhausting air from the combustion chamber 30 ₁. The intake valve 35 ₁ and exhaust valve 36 ₁ are openably/closably operated. The intake valve 35 ₁ and the exhaust valve 36 ₁ are arranged in such a manner as to have operational axial lines L_(I) and L_(O) crossing each other into an approximately V-shape on a projection plane perpendicular to the axial line of the crank shaft 28 and including the axial line of the first cylinder bore 29 ₁ (see FIG. 4). Furthermore, on the projection plane, an angle α_(I) formed between the axial line L_(C) of the first cylinder bore 29 ₁ and the operational axial line L_(I) of the intake valve 35 ₁, is larger than an angle α_(O), formed between the axial line L_(C) of the first cylinder bore 29 ₁ and the operational axial line L_(O) of the exhaust valve 36 ₁ (α_(I)>α_(O)). Furthermore, the intake valve 35, and the exhaust valve 36 ₁ are arranged in the first cylinder head 27 ₁ in such a manner that a crossing point P_(CI) at which the operational axial lines L_(I) and L_(O) of the intake valve 35 ₁ and the exhaust valve 36 ₁ cross each other on the projection plane is lower than the axial line L_(C) of the first cylinder bore 29 ₁.

An intake valve 35 ₂ for opening/closing the intake port 33 ₂ in communication with the combustion chamber 30 ₂ thereby taking air in the combustion chamber 30 ₂, and an exhaust valve 36 ₂ for opening/closing the exhaust port 34 ₂ in communication with the combustion chamber 30 ₂ thereby taking air in the combustion chamber 30 ₂ are arranged in the second cylinder head 27 ₂ in accordance with the same angular and positional relationship as that for the intake valve 35 ₁ and the exhaust valve 36 ₁ arranged in the first cylinder head 27 ₁.

A first head cover 37 ₁ (or second head cover 37 ₂), which forms a first valve system chamber 38, (or second valve system chamber 38 ₂) between the first cylinder head 27 ₁ (or 27 ₂) and the same, is connected to the first cylinder head 27 ₁ (or second cylinder head 27 ₂). A first valve system mechanism 39 ₁ for opening/closing the intake valve 35 ₁ and the exhaust valve 36 ₁ is contained in the first valve system chamber 38 ₁ and a second valve system mechanism 39 ₂ for opening/closing the intake valve 35 ₂ and the exhaust valve 36 ₁ is contained in the second valve system chamber 38 ₂.

The first valve system mechanism 39 ₁ includes a first cam shaft 40 ₁ having an axial line parallel to the axial line of the crank shaft 28, an intake side rocker arm 41 for converting the rotational motion of the cam shaft 40 ₁ into the linear opening/closing motion of the intake valve 35 ₁, and an exhaust side rocker arm 42 for converting the rotational motion of the first cam shaft 40 ₁ into the linear opening/closing motion of the exhaust valve 36 ₁.

The first cam shaft 40 ₁ is located above the axial line L_(C) of the first cylinder bore 29 ₁ and between the intake valve 35 ₁ and the exhaust valve 36 ₁. The first cam shaft 40 ₁ is rotatably supported by the first cylinder head 27 ₁ and a holder 43 connected to the first cylinder head 27 ₁.

The first cam shaft 40 ₁ has an intake side cam 44 corresponding to the intake valve 3 ₁, and an exhaust side cam 45 corresponding to the exhaust valve 36 ₁. The intake side and exhaust side rocker arms 41 and 42 are respectively swingably supported by supporting shafts 46 and 47 which have axial lines parallel to the first cam shaft 40 ₁ and are supported by the holder 43. One-sided ends of the intake side and exhaust side rocker arms 41 and 42 are slidably in contact with the intake side and exhaust side cams 44 and 45, respectively. Tappet screws 48 and 49 are fittingly screwed in the other ends of the intake side and exhaust side rocker arms 41 and 42, respectively. The intake and exhaust valves 35 ₁ and 36 ₁, which are biased in the valve closing direction by valve springs 50 and 51 provided between the first cylinder head 27 ₁ and the same, are in contact with the tappet screws 48 and 49, respectively.

A second valve system mechanism 39 ₂ contained in a valve system chamber 38 ₂ provided between the second cylinder head 27 ₂ and the second head cover 37 ₂ has a second cam shaft 40 ₂ and is configured like the first valve system mechanism 39 ₁.

Referring particularly to FIG. 5, in the front case half 26 a of the crank case 26, the first and second cylinder block 25 ₁ and 25 ₁, and the first and second cylinder heads 27 ₁ and 27 ₂, a cam chain chamber 52 for communicating both of the valve system chambers 38 ₁ and 38 ₂ with the crank case 26 is provided on the offset side of the axial line of the first cylinder bore 29 ₁ from the axial line of the second cylinder bore 29 ₂, i.e., on the front end side of the motorcycle in the longitudinal direction.

A driven sprocket 53 ₁ is fixed to one end portion, on the cam chain chamber 52 side, of the first cam shaft 40 ₁ of the first valve system mechanism 39 ₁, and a driven sprocket 53 ₂ is fixed to one end portion, on the cam chain chamber 52 side, of the second cam shaft 40 ₂ of the second valve system mechanism 39 ₂. In the cam chain chamber 52 ₁ a drive sprocket 54 ₁ corresponding to the driven sprocket 53 ₁ and a drive sprocket 54 ₂ corresponding to the driven sprocket 53 ₂ are fixed to the crank shaft 28. An endless cam chain 55 ₁ is wound around the drive sprocket 54 ₁ and the driven sprocket 53 ₁ for transmitting the rotational power of the crank shaft 28 reduced into half to the first cam shaft 40 ₁. An endless cam chain 55 ₂ is wound around the drive sprocket 54 ₂ and the driven sprocket 53 ₂ for transmitting the rotational power of the crank shaft 28 reduced into half to the second cam shaft 40 ₂.

In accordance with the offset of the axial line of the first cylinder bore 29 ₁ from the axial line of the second cylinder bore 29 ₂ by the offset amount L₁ in the axial direction of the crank shaft 28, the combination of the drive sprocket 54 ₁, the driven sprocket 53 ₁ and the cam chain 55 ₁ is offset from the combination of the drive sprocket 54 ₂, the driven sprocket 53 ₂, and the cam chain 55 ₂ by an offset amount L₂ in the axial direction of the crank shaft 28. In this case, in order to miniaturize the engine main body in the axial direction of the crank shaft 28, the offset amount L₂ is set to be smaller than the offset amount L₁ (L₂<L₁).

The crank shaft 28 is rotated in the rotational direction shown by an arrow 58 in FIG. 5. A chain tensioner 59 ₁ is elastically, slidably in contact with the forward running portion, i.e., the upper running portion of the cam chain 55 ₁ in the direction from the drive sprocket 54 ₁ to the driven sprocket 53. A chain guide 60 ₁ is slidably in contact with the backward running portion, i.e., the lower running portion of the cam chain 55 ₁ in the direction from the driven sprocket 53 ₁ to the drive sprocket 54 ₁.

One end portion of the chain tensioner 59 ₁ is turnably supported by the crank case 26. A tensioner lifter 61 ₁, which is in contact with an intermediate portion of the chain tensioner 59 ₁ in the longitudinal direction and presses the chain tensioner 59 ₁ to the cam chain 55 ₁, is mounted in the upper portion of the first cylinder block 25 ₁.

A chain tensioner 59 ₂ is elastically, slidably in contact with the forward running portion, i.e., the lower running portion of the cam chain 55 ₂ in the direction from the drive sprocket 54 ₂ to the driven sprocket 53 ₁. A chain guide 60 ₁ is slidably in contact with the backward running portion, i.e., the upper running portion of the cam chain 55 ₁ in the direction from the driven sprocket 53 ₂ to the drive sprocket 54 ₂.

One end portion of the chain tensioner 59 ₂ is turnably supported by the crank case 26. A tensioner lifter 61 ₂, which is in contact with an intermediate portion of the chain tensioner 59 ₂ in the longitudinal direction and presses the chain tensioner 59 ₂ to the cam chain 55 ₂, is mounted in the lower portion of the second cylinder block 25.

The front case half 26 a of the crank case 26 has an opening 62 at the front end in the longitudinal direction of the motorcycle. A case 64 for a power generator 63 coaxially connected to the crank shaft 28 in the cam chain chamber 52 is fastened to the front case half 26 a in such a manner as to close the opening 62.

Referring particularly to FIGS. 6 and 7, breather chamber 65 is provided for the second cylinder block 25 ₂, the second cylinder head 27 ₂, and the front case half 26 a of the crank case 26 in such a manner as to be located between the cam chain chamber 52 and the second cylinder bore 29 ₂.

A through-hole 66 extending in parallel to the axial line of the second cylinder bore 29 ₂ is provided in the lower portion of the second cylinder block 25 ₂ in such a manner as to be located between the cam chain chamber 52 and the second cylinder bore 29 ₂. A through-hole 67 extending in parallel to the axial line of the second cylinder bore 29 ₂ is provided in the upper portion of the second cylinder block 25 ₂ in such a manner as to be located between the cam chain chamber 52 and the second cylinder bore 29 ₂. A partition wall 68 is interposed between the through-hole 66 and the through-hole 67.

The breather chamber 65 is composed of a first chamber 65 a formed between the second cylinder block 25 ₂ and the crank case 26, a second chamber 65 b formed in one through-hole 66 of the through-holes 66 and 67, a third chamber 65 c formed between the second cylinder block 25 ₂ and the second cylinder head 27 ₂, and a fourth chamber 65 d formed in the other through-hole 67 of the through-holes 66 and 67.

A through-hole 69 for communicating the first chamber 65 a into the crank case 26 is provided in the front case half 26 a of the crank case 26. A lubricating oil passage 72 is formed between a projecting portion 70 and a rising portion 71. The projecting portion 70 is provided in the through-hole 67 in such a manner as to be integrated with a portion, near the crank case 26, of the second cylinder block 25 ₂. The rising portion 71 is provided on the crank case 26 in such a manner as to be matched with the projecting portion 70. The through-hole 69 is provided in the crank case 26 at a position which is lower than the rising portion 71 to the through-hole 66. A gasket 73 is provided between the crank case 26 and the second cylinder block 25 ₂ for blocking communication between the first chamber 65 a and the fourth chamber 65 d. The gasket 73 has an opening 74 for communicating the first chamber 65 a to the second chamber 65 b. A gasket 75 is provided between the second cylinder block 25 ₂ and the second cylinder head 27 ₂. The gasket 75 has an opening 76 for commonly communicating the second and fourth chambers 65 b and 65 d to the third chamber 65 c.

Accordingly, the first chamber 65 a is in communication with the crank case 26; the second chamber 65 b formed in one through-hole 66 is in communication with the first chamber 65 a; the third chamber 65 c is in communication with the second chamber 65 b; and the fourth chamber 65 d formed in the other through-hole 67 is in communication with the third chamber 65 c but is blocked from communicating with the first chamber 65 a. A breather gas outlet 77 in communication with the fourth chamber 65 d is provided in the upper portion of the second cylinder block 25 ₂.

Referring particularly to FIG. 8, an intake manifold 80 is connected to the intake ports 33 ₁ and 33 ₂ of the first and second cylinder heads 27 ₁ and 27 ₂. The intake manifold 80 is composed of an intake pipe 81 ₁, an intake pipe 81 ₂, and a common pipe portion 82. One end of the intake pipe 81 ₁ is connected to the intake port 33 ₁ of the first cylinder head 27 ₁ and the other end of the intake pipe 81 ₁ is connected to the common pipe portion 82. One end of the intake pipe 81 ₂ is connected to the intake port 33 ₂ of the second cylinder head 27 ₂ and the other end of the intake pipe 81 ₂ is connected to the common pipe portion 82. The common pipe portion 82 is connected to the air cleaner 23 (see FIG. 1) via a throttle body (not shown).

Referring again to FIG. 4, the intake pipe 81 ₁ includes a first straight pipe portion 83, a second straight pipe portion 84, and a bent pipe portion 85. The first straight portion 83 extends along a first straight center line CL₁ and has a downward end connected to the intake port 33 ₁. The second straight pipe portion 84 extends along a second straight center line CL₂ crossing the first center line CL₁. The bent pipe portion 85 is formed into a circular-arc shape while connecting the upstream end of the first straight pipe portion 83 to the downstream end of the second straight pipe portion 84. The upstream end of the second straight pipe portion 84 is connected to the common pipe portion 82. A fuel injection valve 86 ₁ for injecting fuel to the intake port 33 ₁ side is held between a portion, near the intake port 33 ₁, of the intake pipe 81 and a mounting member 87 ₁ fastened to the intake pipe 81 ₁.

A mounting flange 88 projecting outwardly is provided on an intermediate portion of the fuel injection valve 86 ₁. A fitting hole 89 in which the leading end of the fuel injection valve 86 ₁ is to be fitted is provided in the intake pipe 81 ₁, and a seat 90 for receiving the mounting flange 88 is formed around an outer end portion of the fitting hole 89. In this case, the fitting hole 89 and the seat 90 are located in the intake pipe 81 ₁ at a portion which is closer to the intake port 33, than a straight line 91 which connects a crossing point P_(C2) where the first and second center lines CL₁ and CL₂ cross each other and a curved center C_(C) of the bent pipe portion 85.

A pair of fastening portions 92 and 93 are provided on the mounting member 87 ₁. Both of the fastening portions 92 and 93 of the mounting member 87 ₁, in which the outer end of the fuel injection valve 86 ₁ is fitted, are fastened to a pair of fastening seats 94 and 95 provided on the intake pipe 81 ₁ by means of a pair of bolts 96 and a pair of bolts 97, respectively. Both of the fastening seats 94 and 95 are provided at such a position as to hold the straight line 91 between the seat 90 and the same. The fastening portions 92 and 93 are formed in parallel with the seat 90.

A fuel passage 98 ₁, which extends in a direction tilting at an acute angle formed with respect to the second center line CL₂ of the second straight pipe portion 84 and which is in communication with the outer end of the fuel injection valve 86 ₁, is formed in the mounting member 87 ₁.

The intake pipe 81 ₂ connected to the intake port 33 ₂ of the second cylinder head 27 ₂ is configured like the intake pipe 81 ₁. A fuel injection valve 86 ₂ is held between the intake pipe 81 ₂ and a mounting member 87 ₂ mounted to the intake pipe 81 ₂. The fuel injection valve 86 ₂ is mounted to the intake pipe 81 ₂ in accordance with basically the same the structure as that for mounting the fuel injection valve 86 ₁ to the intake pipe 81 ₁. Like the fuel passage 98 ₁ formed in the mounting member 87 ₁ a fuel passage 98 ₂ in communication with the fuel injection valve 86 ₂ is formed in the mounting member 87 ₂.

The fuel passages 98 ₁ and 98 ₂ of both of the mounting members 87 ₁ and 87 ₂ are in communication with each other via a fuel conduit 99 disposed along the second straight pipe portions 84 of the intake pipes 81 ₁ and 81 ₂. A fuel feed pipe 101, to which fuel having been pumped from the fuel tank 22 by the fuel pump 100 (see FIG. 1) is fed from the fuel pump 100, is connected to one mounting member 87 ₁ of both of the mounting members 87 ₁ and 87 ₂. The other mounting member 87 ₁ is additionally provided with a regulator 102 for regulating a fuel pressure in the fuel passages 98 ₁ and 98 ₂ and the fuel conduit 99. A fuel return pipe 103 for returning excess fuel to the fuel tank 22 is connected to the regulator 102.

An exhaust manifold 106 is connected to the exhaust ports 34 ₁ and 34 ₂ of the first and second cylinder heads 27 ₁ and 27 ₂. The exhaust manifold 106 includes an exhaust pipe 107 ₁ having one end connected to the exhaust port 34 ₁ of the first cylinder head 27 ₁ and an exhaust pipe 107 ₂ having one end connected to the exhaust port 34 ₂ of the second cylinder head 27 ₂. The other ends of the exhaust pipes 107 ₁ and 107 ₂ are connected to each other on the right side of the transmission case 15 when the motorcycle is directed forwardly in the running direction, and extend to the rear side of the motorcycle.

An ignition plug 108 ₁ (or 108 ₂) having a leading end protruding into the combustion chamber 30 ₁ (or 30 ₂) is provided in the rear side, along the longitudinal direction of the motorcycle, of the cylinder head 27 ₁ (or 27 ₂) in such a manner as to be gradually tilted onto the cylinder block 25 ₁ (or 25 ₂) in the direction toward the outer end side of the ignition plug 108 ₁ (or 108 ₂). A mounting hole 109 ₁ (or 109 ₁) for mounting the ignition plug 108 ₁ (or 108 ₂) is provided in the cylinder head 27 ₁ (or 27 ₂) in such a manner as to be opened rearwardly in the longitudinal direction of the motorcycle. Since the mounting hole 109 ₁ (or 109 ₂) for mounting the ignition plug 108 ₁ (or 108 ₂) is opened rearwardly, it is possible to prevent water, mud and the like splashed up upon running of the motorcycle from permeating into the mounting hole 109 ₁ (or 109 ₂) as much as possible, and hence to eliminate the necessity of provision of a plug cap and the like and also eliminate the necessity of forming a drain opening in communication with the mounting hole 109 ₁ (or 109 ₂) in the cylinder head 27 ₁ (or 27 ₂).

Referring particularly to FIGS. 9 and 10, a secondary air feed passage 110 for feeding secondary air to exhaust gas flowing in the exhaust port 34 ₂ is provided in the second cylinder head 27 ₂. The secondary air feed passage 110 is composed of a first passage portion 111 and a second passage portion 112. The first passage portion 111 extends in a straight line with one end opened to a portion, near the exhaust valve 36 ₁, of the inner surface of the exhaust port 34 ₂ towards the downstream side of the flowing direction of exhaust gas. The second passage portion 112, which has a straight axial line bent from the axial line of the first passage portion 111 to the second cylinder block 25 ₂ side, is connected to an intermediate portion of the first passage portion 111. To be more specific, the first passage portion 111 is formed by piercing the second cylinder head 27 ₂ in straight line from the upper surface of the second cylinder head 27 ₂ to the exhaust port 34 ₂. The outer end portion of the first passage portion 111 is blocked with a plug 113. One end of the second passage portion 112 is in communication with the intermediate portion of the first passage portion 111, and the other end of the second passage portion 112 is opened to the connection plane of the second cylinder head 27 ₂ to which the second cylinder block 25 ₂ is connected.

A valve case 114 for a reed valve 115 ₂ is mounted on the upper surface of the second cylinder block 25 ₂ at a position near the second cylinder head 27 ₂. A communication passage 116 for communicating the reed valve 115 ₂ to the second passage portion 112 of the secondary air feed passage 110 is provided in the second cylinder block 25 ₂. A connection pipe portion 117 is integrally provided with the valve case 114, and is connected to a control valve (not shown).

Like the second cylinder head 27 ₂, the first cylinder head 27 ₁ is provided with a secondary air feed passage (not shown) in communication with the exhaust port 34 ₁, and a reed valve 115 ₁ connected to the second air feed passage is mounted on the upper surface of the first cylinder block 25 ₁.

A first cooling jacket 118 ₁ is provided in the first cylinder block 25 ₁ and the first cylinder head 27 ₁, and a second cooling jacket 118 ₂ is provided in the second cylinder block 25 ₂ and the second cylinder head 27 ₂.

The second cooling jacket 118 ₂ is composed of a cylinder side cooling water passage 119 ₂ provided in the second cylinder block 25 ₂ in such a manner as to surround the second cylinder bore 29 ₂, and a head side cooling water passage 120 ₂ provided in the second cylinder head 27 ₂ in such a manner as to be in communication with the cylinder side cooling water passage 119 ₂.

Referring to FIG. 7, the second cylinder block 25 ₂ is provided with a partition wall 121 which extends in parallel to the axial line of the second cylinder bore 29 ₂ and which partitions the cylinder side cooling water passage 119 ₂. A water inlet 122 ₂ in communication with the cylinder side cooling water passage 119 ₂ on one side of the partition wall 121 is provided beneath the second cylinder block 25 ₂.

On the other hand, as shown in FIG. 9, a pair of communication passages 123 and 124 for communicating the cylinder side cooling water passage 119 ₂ to the head side cooling water passage 120 ₂ on the other side of the partition wall 121 are provided in the second cylinder head 27 ₂. A water outlet 125, which is in communication with the head side cooling water passage 120 ₂ on the side being substantially opposed to the communication passages 123 and 124 with respect to the combustion chamber 302, is provided at the upper portion of he second cylinder head 27 ₂.

To be more specific, both of the communication passages 123 and 124 allow the cylinder side cooling water passage 119 ₂ to communicate with the head side cooling water passage 120 ₂ via an opening (not shown) provided in the gasket 73 provided between the second cylinder block 25 ₂ and the second cylinder head 27 ₂. Both of the communication passages 123 and 124 are provided in the second cylinder head 27 ₂ in proximity to each other in such a manner that the one communication passage 124 is disposed substantially corresponding to the ignition plug 108 ₂.

The first cooling jacket 118 ₁ includes a cylinder side cooling water passage 119 ₁, provided in the first cylinder block 25 ₁, in such a manner as to surround the first cylinder bore 29 ₁, and a head side cooling water passage 120 ₁, provided in the first cylinder head 27 ₁ in such a manner as to be in communication with the cylinder side cooling water passage 119 ₁. The first cooling jacket 118 ₁ is configured like the second cooling jacket 118 ₂. A water inlet 121 ₁ in communication with the cylinder side cooling water passage 119 ₁ is provided in a lower portion of the first cylinder block 25 ₁, and a water outlet (not shown) in communication with the head side cooling water passage 120 ₁ is provided on an upper portion of the first cylinder head 27.

Referring to particularly to FIGS. 11 and 12, a single water pump 128 is mounted to the crank case 26 in such a manner as to be located under the lowermost portions of the first and second cooling jackets 181 ₁ and 118 ₂ and between both of the cooling jackets 181 ₁ and 118 ₂.

A pump housing 129 of the water pump 128 includes a pump body 130 for rotatably supporting a pump shaft 132 ₁ and a pump cover 131 fastened to the pump body 130 in such a manner as to cover an impeller 133 fixed to the pump shaft 132.

The pump body 130 is fastened to the front case half 26 a of the crank case 26 in such a manner that a supporting cylinder portion 130 a integrated with the pump body 130 air-tightly protrudes into the front case half 26 a. The pump cover 131 is fastened to the pump body 130, to form a circular pump chamber 134 coaxial with the pump shaft 132 between the pump body 130 and the pump cover 131.

The pump shaft 132 is liquid-tightly and rotatably supported by the supporting cylinder portion 130 a of the pump body 130 in a state in which one end thereof protrudes into the pump chamber 134. The impeller 133 disposed in the pump chamber 134 is fixed to the other end of the pump shaft 132.

An upper discharge passage 135 and a lower discharge passage 136 are formed in the pump housing 129. The upper discharge passage 135 is connected to an upper end portion of the pump chamber 134 and extends obliquely, upwardly therefrom along the tangential direction of the outer edge of the pump chamber 134. The lower discharge passage 136 is connected to a lower end portion of the pump chamber 134 and extends obliquely, downwardly therefrom along the tangential direction of the outer edge of the pump chamber 134. A first connection pipe 137 extending in a straight line from the upper discharge passage 135 and a second connection pipe 138 extending in a straight line from the lower discharge passage 136 are integrally provided on the pump body 130 of the pump housing 129 in such a manner that the inner ends of the first and second connection pipes 137 and 138 are in communication with the upper and lower discharge passages 135 and 136, respectively. Furthermore, the first and second discharge ports 139 and 140 are formed at the outer ends of the first and second connection pipes 137 and 138, respectively.

Referring again to FIG. 2, the first discharge port 139 formed at the outer end of the first connection pipe 137 is connected to the water inlet 122 ₁ formed in the first cooling jacket 118 ₁ for the first cylinder block 25 ₁ and the first cylinder head 27 ₁ through the first conduit 141. The first discharge port 140 formed at the outer end of the second connection pipe 138 is connected to the water inlet 122 ₂ formed in the second cooling jacket 118 ₂ for the second cylinder block 25 ₂ and the second cylinder head 27 ₂ through the second conduit 142. The length of the first conduit 141 is set to be shorter than the length of the second conduit 142. In other words, the difference in length between the first and second conduits 141 and 142 is determined such that the flow resistance corresponding to the difference in pump head between the first and second discharge ports 139 and 140 of the water pump 128 is allowed to occur on the second conduit 142 side.

The pump cover 131 has first and second suction ports 143 and 144 in communication with the pump chamber 134. The first suction port 143 is connected to a thermostat (not shown) and the second suction port 144 is connected to the radiators 24 (see FIG. 1).

If the temperature of cooling water is low before warming of the engine E, the thermostat is operated to return cooling water discharged from the water pump 128 to the first suction port 143 by way of only the first and second cooling jackets 118 ₁ and 118 ₂, i.e., not by way of the radiators 24. However, if the temperature of cooling water becomes high after tarming of the engine E, the thermostat is operated to return cooling water discharged from the water pump 128 to the second suction port 144 by way of not only the first and second cooling jackets 181 ₁ and 118 ₂ but also the radiators 24.

A trochoid type oil pump 146 for feeding lubricating oil to portions to be lubricated of the engine E is provided on the inner surface, on the transmission case 15 side, of the rear case half 26 b of the crank case 26 in such a manner as to be coaxial with the water pump 128.

A pump housing 147 of the oil pump 146 is composed of a pump body 148 integrally formed on the rear case half 26 b and a pump cover 149 fastened to the pump body 148. A pump shaft 150 coaxial with the pump shaft 132 of the water pump 128 is rotatably supported by the pump housing 147. A pinion 151 is fixed to the pump shaft 150 in the pump housing 147, and an inner gear 152 meshed with the pinion 151 is rotatably supported by the pump housing 147. A strainer 154 is connected to a suction port 153 of the oil pump 146.

One end of the pump shaft 150 of the oil pump 146 faces to the other end of the pump shaft 132, projecting from the supporting cylinder portion 130 a, of the water pump 128. An engagement plate 156 provided on the one end of the pump shaft 150 is engaged with an engagement recess 155 provided on the other end of the pump shaft 132. That is to say, both of the pump shafts 132 and 150 are connected to each other with relative rotation thereof prevented.

The other end of the pump shaft 150 of the oil pump 146 projects from the pump housing 147 and is located in the transmission case 15, and a driven sprocket 157 is fixed to the other end of the pump shaft 150.

Referring again to FIG. 3, a drive sprocket 158 corresponding to the driven sprocket 157 is fixed to the crank shaft 28 in the transmission case 15. An endless chain 159 is wound around the drive sprocket 158 and the driven sprocket 157 for transmitting the rotational power of the crank shaft 28 to the oil pump 146 and the water pump 128.

Referring to FIG. 13, the crank shaft 28 passes through a bearing hole 161 provided in the rear case half 26 b of the crank case 26 and projects towards the transmission case 15 side. A cylindrical bearing 162 is provided between the outer surface of the crank shaft 28 and the inner surface of the bearing hole 161.

On the outer side of the rear case half 26 b of the crank case 26, i.e., on the transmission case 15 side, a drive gear 163 is fixed on a portion, near the rear case half 26 b, of the crank shaft 28. An over-running clutch 164 is mounted on the crank shaft 28 at a position between the drive gear 163 and the drive sprocket 158.

The drive gear 163 is meshed with a driven gear (not shown) provided on a balancer shaft 165 (see FIG. 2) having an axial line parallel to the crank shaft 28 and rotatably supported by the crank case 26.

The over-running clutch 164 is used for transmitting power from a starter motor 166 (see FIG. 3) mounted to the transmission case 15 to the crank shaft 28, while blocking the power transmission from the crank shaft 28 to the starter motor 166 side. The over-running clutch 164 includes a clutch inner race 168 for coaxially surrounding the crank shaft 28 with a roller bearing 167 interposed between the crank shaft 28 and the same, a ring-shaped clutch outer race 169 for coaxially surrounding the clutch inner race 168, and a plurality of rollers 170 provided between the clutch inner race 168 and the clutch outer race 169.

An output member 171, which is spline-connected to the crank shaft 28 in such a manner as to face toward the drive gear 163, is connected to the clutch outer race 169 by means of a plurality of bolts 173. An input member 172 is fixed to the clutch inner race 168 with the clutch outer race 169 located between the output member 171 and the input member 172. A driven gear 174 is provided on the outer periphery of the input member 172. A first intermediate gear 175 meshed with the driven gear 174 is rotatably supported by the transmission case 15. A second intermediate gear 176 integrated with the first intermediate gear 175 is meshed with a drive gear 177 (see FIG. 3) provided on an output shaft of the starter motor 166.

Lubricating oil is fed from an oiling passage 178 provided in the rear case half 26 b of the crank case 26 to the bearing 162. The bearing 162 has a plurality of through-holes 179 extending from the inner surface to the outer surface of the bearing 162. Accordingly, the lubricating oil fed from the oiling passage 178 is uniformly fed between the outer surface of the bearing 162 and the rear case half 26 b and between the inner surface of the bearing 162 and the outer surface of the crank shaft 28. On the other hand, an oil passage 180 having one end in communication with the through-holes 179 is provided in the crank shaft 28. The oil passage 180 functions to introduce lubricating oil into a connection portion between the crank shaft 28 and the connecting rod 32 ₂.

A projecting portion 181, which projects radially inwardly from the end portion, on the transmission case 15 side, of the bearing hole 161, is integrally provided on the rear case half 26 b of the crank case 26. An annular discharge port 182 for discharging lubricating oil fed to the bearing 162 onto the output member 171 side of the over-running clutch 164 is formed between the projecting portion 181 and the outer surface of the crank shaft 28.

The output member 171 has introducing holes 183 for introducing lubricating oil discharged from the annular discharge port 182 into the over-running clutch 164. The introducing holes 183 are provided at a plurality of positions spaced from each other in the peripheral direction of the output member 171.

The drive gear 163, which is disposed between the annular discharge port 179 and the output member 171, is fixed on the crank shaft 28 and is substantially integrated with the output member 171. Accordingly, a plurality of introducing holes 184 individually corresponding to the introducing holes 183 of the output member 171 are provided in the drive gear 163. With this configuration, lubricating oil discharged from the annular discharge port 182 is introduced in the over-running clutch 164 through the introducing holes 183 and 184 without obstruction by the drive gear 163.

The function of this embodiment will be described below. As described above, in the horizontally-opposed type four-cycle/two-cylinder engine E, the first cam shaft 40 ₁ (or second cam shafts 40 ₂) is disposed above the axial line L_(C) of the first cylinder bore 29 ₁ (or second cylinder bore 29 ₂); and on the projection plane perpendicular to the axial line of the crank shaft 28 including the axial line of the first cylinder bore 29 ₁ (or second cylinder bore 29 ₂), an angle α_(I) formed between the axial line L_(C) of the first cylinder bore 29 ₁ (or second cylinder bore 29 ₂) and the operational axial line L_(I) of the intake valve 35 ₁ (or 35 ₂) is larger than an angle α_(O) formed between the axial line L_(C) of the first cylinder bore 29 ₁ (or the second cylinder bore 29 ₂) and the operational axial line L_(O) of the exhaust valve 36 ₁ (or 36 ₂)

With this configuration, the outer end of the exhaust valve 35 ₁ (or 35 ₂) can be disposed in such a manner as to be made as close to the axial line of the cylinder bore 29 ₁ (or 29 ₂) as possible. Accordingly, it is possible to avoid restriction of the bank angle of the motorcycle at the outer ends of the exhaust valves 35 ₁ and 35 ₂, and hence to make the mounting position of the engine E as low as possible while ensuring the ground clearance of the motorcycle. This is effective to make the center of gravity of the motorcycle lower and also to improve the steering of the motorcycle.

Furthermore, on the projection plane perpendicular to the axial line of the crank shaft 28 including the axial line of the first cylinder bore 29 ₁ (or the second cylinder bore 29 ₂), the crossing point P_(C1) at which the operational axial lines L_(I) and L_(O) of the intake valve 35 ₁ (or 35 ₂) and the exhaust valve 36 ₁ (or 36 ₂) cross each other is located lower than the axial line L_(C) of the cylinder bore 29 ₁ (or 29 ₂). Accordingly, it is possible to easily ensure a squish area of the combustion chamber 30 ₁ (or 30 ₂) on the intake valve 35 ₁ (or 35 ₂) side having a diameter larger than the exhaust valve 36 ₁ (or 36 ₂), and hence to make the squish area on the intake side nearly equal to that on the exhaust side.

The first and second cylinder blocks 25 ₁ and 25 ₂ are commonly connected to the crank case 28 in such a manner that the axial line of the first cylinder bore 29 ₁ of the first cylinder block 25 ₁ is offset from the axial line of the second cylinder bore 29 ₂ of the second cylinder block 25 ₂ onto one side along the axial line of the crank shaft 28. Furthermore, on one side along the axial line of the crank shaft 28, the cam chain chamber 52 is provided for the crank case 26, the cylinder blocks 25 ₁ and 25 ₂ and the cylinder heads 27 ₁ and 27 ₂. Accordingly, a relatively large space is formed between the second cylinder bore 29 ₂ and the cam chain chamber 52, so that a breather chamber 65 can be provided for the crank case 26, the second cylinder block 25 ₂ and the second cylinder head 27 ₂ by making effective use of the space. As a result, it is possible to form the breather chamber 65 having a relatively large capacity while avoiding enlargement of the size of the entire engine, and hence to improve the breather performance.

The breather chamber 65 is composed of the first chamber 65 a in communication with the interior of the crank case 26, the second chamber 65 b in communication with the first chamber 65 a, the third chamber 65 c in communication with the second chamber 65 b, and the fourth chamber 65 d in communication with the third chamber 65 c, but is blocked from the first chamber 65 a; and the breather gas outlet 77 in communication with the fourth chamber 65 d is provided in the second cylinder block 25 ₂. Accordingly, since the breather chamber 65 has a labyrinth structure, it is possible to effectively separate oil mist from breather gas in the breather chamber 65 and hence to further improve the breather performance.

The intake pipe 81 ₁ (or 81 ₂) in communication with the intake port 33 ₁ (or 33 ₂) of the first cylinder head 27 ₁ (or the second cylinder head 27 ₂) includes the first straight pipe portion 83 extending along the first straight center line CL₁, the second straight pipe portion 84 extending along the second straight center line CL₂ crossing the first center line CL₁, and the bent pipe portion 85 formed into a circular-arc shape while connecting the upstream end of the first straight pipe portion 83 to the downstream end of the second straight pipe portion 84; and the fuel injection valve 86 ₁ (or 86 ₂), for injecting fuel to the intake port 33 ₁ (or 33 ₂), is held between the intake pipe 81 ₁ (or 81 ₂) and the mounting member 87 ₁ (or 87 ₂) fastened to the intake pipe 81 ₁ (81 ₂). Furthermore, the seat 90 for receiving the fuel injection valve 86 ₁ (or 86 ₂) is provided in the intake pipe 81 ₁ (or 81 ₂) at a portion which is closer to the intake port 33 ₁ (or 33 ₂) than the straight line 91 which connects the crossing point P_(C2) where the first and second center lines CL₁ and CL₂ cross each other and the curved center C_(C) of the bent pipe portion 85. As a result, it is possible to suppress the projecting amount of the fuel injection valve 86 ₁ (or 86 ₂) from the outer end of the cylinder head 27 ₁ (or 27 ₂) and hence to make the entire engine including the fuel injection system compact.

The fastening seats 94 and 95 for fastening the mounting member 87 ₁ (or 87 ₂) are provided on the intake pipe 81 ₁ (or 81 ₂) with the straight line 91 located between the seat 90 and the same. As a result, the fastening seats 94 and 95 of the mounting member 87 ₁ (or 87 ₂) are provided on the second straight pipe portion 84 side while the outer end of the fuel injection valve 86 ₁ (or 86 ₂) is disposed at a position relatively far away from the first center line CL₁, so that a space for disposing the mounting member 87 ₁ (or 87 ₂) can be relatively largely ensured.

Since the seat 90 and the fastening seats 94 and 95 are formed in parallel to each other, it becomes easy to mount the fuel injection valve 86 ₁ (or 86 ₂) to the intake pipe 81 ₁ (or 81 ₂), and also it is possible to improve the mounting reliability.

The fuel passage 98 ₁ (or 98 ₂), which extends in a direction tilting at an acute angle formed with respect to the second center line CL₂ and which is connected to the fuel injection valve 86 ₁ (or 86 ₂), is formed in the mounting member 87 ₁ (or 87 ₂), so that the fuel conduit 99 connected to the fuel passage 98 ₁ (or 98 ₂) can be disposed along the second straight pipe portion 84 of the intake pipe 81 ₁ (or 81 ₂). Accordingly, it is easy to ensure a space for disposing the fuel conduit 99 and to protect the fuel conduit 99. This is advantageous in preventing occurrence of vapor gas due to vibration of the fuel conduit 99.

The secondary air feed passage 110 for feeding secondary air to exhaust gas flowing in the exhaust port 34 ₁ (or 34 ₂) is provided in the first cylinder head 27 ₁ (or second cylinder head 27 ₂). The secondary air feed passage 110 is composed of the first passage portion 111 and the second passage portion 112. The first passage portion 111 extends in a straight line having one end opened in the inner surface of the exhaust port 34 ₁ (or 34 ₂) onto the downstream side of the flowing direction of exhaust gas. The second passage portion 112, which has a straight axial line bent from the axial line of the first passage portion 111 onto the cylinder block 25 ₁ (or 25 ₂) side, is connected to the first passage portion 111.

The shape of the secondary air feed passage 110 causes the secondary air to be sucked from the secondary air feed passage 110 into the exhaust port 34 ₁ (or 34 ₂) by the flow of exhaust gas in the exhaust port 34 ₁ (or 34 ₂). This makes it possible to prevent the permeation of exhaust gas into the secondary air feed passage 110 as mush as possible. Furthermore, the second passage portion 112 is in communication with the first passage portion 111 in such a manner as to be bent from the first passage portion 111. Accordingly, even if exhaust gas permeates in the first passage portion 111 of the secondary air passage 110, it is possible to prevent the exhaust gas thus permeated in the first passage portion 111 from further permeating into the second passage portion 112 side, and hence to shorten the length of the secondary air feed passage 110.

Since the reed valve 115 ₁ (or 115 ₂) connected to the secondary air feed passage 110 is mounted on the outer surface of the cylinder block 25 ₁ (or 25 ₂), it is possible to avoid the enlargement of the entire engine accompanied by arrangement of the reed valve 115 ₁ (or 115 ₂).

The first cooling jacket 118 ₁ is provided in the first cylinder block 25 ₁ and the first cylinder head 27 ₁, and the second cooling jacket 118 ₂ is provided in the second cylinder block 25 ₂ and the second cylinder head 27 ₂. The cooling jacket 118 ₁ (or 118 ₂) is composed of the cylinder side cooling water passage 119 ₁ (or 119 ₂) provided in the cylinder block 25 ₁ (or 25 ₂) in such a manner as to surround the cylinder bore 29 ₁ (or 29 ₂). The head side cooling water passage 120 ₁ (or 120 ₂) is provided in the cylinder head 27 ₁ (or 27 ₂) in such a manner as to be in communication with the cylinder side cooling water passage 119 ₁ (or 119 ₂). The cylinder block 25 ₁ (or 25 ₂) is provided with a partition wall 121 which extends in parallel to the axial line of the cylinder bore 29 ₁ (or 29 ₂) for partitioning the cylinder side cooling water passage 119 ₁ (or 119 ₂). The water inlet 122 ₁ (or 122 ₂) in communication with the cylinder side cooling water passage 119 ₁ (or 119 ₂) is provided in the cylinder block 25 ₁ (or 25 ₂) on one side of the partition wall 121. The cylinder head 27 ₁ (or 27 ₂) has a pair of communication passages 123 and 124 on the other side of the partition wall 121 for communicating the cylinder side cooling water passage 119 (or 119 ₂) to the head side cooling water passage 120 ₁ or (120 ₂).

Accordingly, cooling water which has been fed from the water inlet 122 ₁ (or 122 ₂) to the cylinder side cooling water passage 119 ₁ (or 119 ₂) on the one side of the partition wall 121, flows in the cylinder side cooling water passage 119 ₁ (or 119 ₂) toward the other side of the partition wall 121 in such a manner as to substantially go around the cylinder bore 29 ₁ (or 29 ₂). The cooling water is then introduced to the head side cooling water passage 120 ₁ (or 120 ₂) via the communication passages 123 and 124.

On the other hand, the cylinder head 27 ₁ (or 27 ₂) has the water outlet 125 which is located substantially opposite to the communication passages 123 and 124 with respect to the combustion chamber 30 ₁ (or 30 ₂) in such a manner as to be in communication with the cylinder side cooling water passage 120 ₁ (or 120 ₂). Accordingly, the cooling water having been introduced in the head side cooling water passage 120 ₁ (or 120 ₂) flows in the head side cooling water passage 120 ₁ (or 120 ₂) toward the water outlet 125 disposed substantially opposite to the communication passages 123 and 124 with respect to the combustion chamber 30 ₁ (or 30 ₂).

To be more specific, cooling water smoothly flows from the water inlet 122 ₁ (or 122 ₂) to the water outlet 125 by way of the cylinder side cooling water passage 119 ₁ (or 119 ₂), the communicating passages 123 and 124, and the head side cooling water passage 120 ₁ (or 120 ₂). As a result, it is possible to effectively cool the cylinder blocks 25 ₁ and 25 ₂ and the cylinder heads 27 ₁ and 27 ₂.

The ignition plug 108 ₁ (or 108 ₂) having a leading end protruding in the combustion chamber 30 ₁ (or 30 ₂) is provided in the cylinder head 27 ₁ (or 27 ₂) in such a manner as to be tilted onto the cylinder block 25 ₁ (or 25 ₂) in the direction toward the outer end side of the ignition plug 108 ₁ (or 108 ₂). One communication passage 124 of both of the communication passages 123 and 124 is disposed at a position substantially corresponding to the ignition plug 108 ₁ (or 108 ₂). As a result, the flow area of a portion, corresponding to the communication passage 124, of the head side cooling water passage 120 ₁ (or 120 ₂) becomes inevitably small, so that it is possible to improve the cooling performance of the cylinder head 27 ₁ (or 27 ₂) in the vicinity of the ignition plug 108 ₁ (or 108 ₂) by increasing the flow rate of cooling water at the above portion of the head side cooling water passage 120 ₁ (or 120 ₂).

The single water pump 128 commonly used for the first and second cooling jackets 118 ₁ and 118 ₂ is disposed under the lowermost portions of both of the cooling jackets 118 ₁ and 118 ₂ and between both of the cooling jackets 118 ₁ and 118 ₂. The first and second discharge ports 139 and 140 of the water pump 128 are connected to the water inlets 122, and 122 ₂ of both of the cooling jackets 118 ₁ and 118 ₂, respectively.

The pump housing 129 of the water pump 128 contains a circular pump chamber 134 for rotatably containing the impeller 133; the upper discharge passage 135 connected to the upper end of the pump chamber 134 and extending obliquely, upwardly therefrom; and the lower discharge port 136 connected to the lower end of the pump chamber 134 and extending obliquely, downwardly therefrom. The first and second connection pipes 137 and 138 with their outer end openings taken as the first and second discharge ports 139 and 140 are arranged continuously to the pump housing 129 in such a manner that they extend in straight lines from the upper and lower discharge passages 135 and 136 and the inner ends thereof are in communication with the upper and lower discharge passages 135 and 136, respectively.

Accordingly, the path from the upper end of the pump chamber 134 to the first discharge port 139 at the outer end of the first connection pipe 137 by way of the upper discharge passage 135 extends obliquely in such a manner that the first discharge port 139 is located at the highest position, while the path from the lower end of the pump chamber 134 to the second discharge port 140 at the outer end of the second connection pipe 138 by way of the lower discharge passage 136 extends obliquely in such a manner that the lower end of the pump chamber 134 is located at the highest position. To be more specific, the path from the second discharge port 140 to the first discharge port 139 by way of the lower discharge passage 136, the pump chamber 134, and the upper discharge passage 135 does not have any portion in which air remains. As a result, it is possible to eliminate the necessity of providing a structure specialized for ventilation such as an air vent bolt and to easily extract air from the water pump 128.

The first discharge port 139 is connected to the first cooling jacket 118 ₁ by means of the first conduit 141, and the second discharge port 140 is connected to the second cooling jacket 118 ₂ by means of the second conduit 142. Furthermore, the length of the first conduit 141 is set to be shorter than that of the second conduit 142 in order that the flow resistance corresponding to the difference in pump head between the first and second discharge ports 139 and 140 of the water pump 128 is allowed to occur on the second conduit 142 side. As a result, since the difference in pump head between the first and second discharge ports 139 and 140 of the water pump 128 is balanced with the flow resistance occurring at the first and second conduits 141 and 142, it is possible to uniformly feed cooling water from the common water pump 128 to the first and second cooling jackets 118 ₁ and 118 ₂.

The over-running clutch 164 including the input member 172 to which power is inputted from the starter motor 166 and the output member 171 connected to the crank shaft 28 is mounted on the crank shaft 28 in the transmission case 15. The bearing hole 161 allowing the crank shaft 28 to pass therethrough is provided in the rear case half 26 b of the crank case 26, and the bearing 162 is provided between the inner surface of the bearing hole 161 and the outer surface of the crank shaft 28.

Furthermore, the over-running clutch 164 is mounted to the crank shaft 28 with its output member 171 disposed on the bearing 162 side, and the annular discharge port 182 is formed between the projecting portion 181 and the outer surface of the crank shaft 28. The projecting portion 181 is integrally provided on the rear case half 26 b of the crank case 26 in such a manner as to project radially inwardly from the end, on the transmission case 15 side, of the bearing hole 161. The oiling passage 178 for feeding lubricating oil to the bearing 162 is provided in the rear case half 26 b of the crank case 26. Accordingly, the lubricating oil fed to the bearing 162 is discharged from the annular discharge port 182 onto the output member 171 side of the over-running clutch 164.

The output member 171 has introducing holes 183 for introducing the lubricating oil discharged from the annular discharge port 182 into the over-running clutch 164.

Accordingly, when the lubricating oil fed to the bearing 162 is discharged from the annular discharge port 182 onto the output member 171 of the over-running clutch 164, the lubricating oil is correspondingly introduced from the introducing holes 183 of the output member 171 rotated together with the crank shaft 28 into the over-running clutch 164. As a result, it is possible to eliminate the necessity of forming lubricating oil feed holes in the over-running clutch 164, and hence to reduce the number of processing steps and the manufacturing cost. Furthermore, since the lubricating oil fed from the bearing 162 is used for lubricating the over-running clutch 164, it is possible to miniaturize the oil pump 146 without decreasing the amount of lubrication oil discharged from the oil pump 146.

An embodiment of the present invention has been described in detail above, but the present invention is not limited to this embodiment and various modifications and design changes are possible without departing from the spirit and scope of the invention as disclosed in the appended claims.

For example, in the above described embodiment, description has been given for a horizontally opposed engine, but the present invention can also be applied to a V-type engine. The present invention can also be applied to an engine with a plurality of cylinders provided in each cylinder block.

According to the first aspect of the present invention, a passageway from an upper end of a pump chamber through an upper discharge path and leading to a first discharge port at an outer end of a first connecting pipe extends diagonally so that the first discharge port is at the highest position, while a passageway from a lower end of the pump chamber through a lower discharge path and leading to a second discharge port at an outer end of a second connecting pipe extends diagonally so that the lower end of the pump chamber is at the lowest position. This prevents a section where air is accumulated in the water pump, and therefore there is no need to provided a dedicated structure for removing air from the pump, such as air removal bolts. Furthermore, it is possible to easily remove air from the water pump.

According to the second aspect of the present invention, it is possible to supply equal amounts of cooling water to both of the first and second cooling jackets by balancing a difference in height between first and second discharge ports of a water pump and a flow resistance arising in first and second connecting pipes.

The invention being thus described, it will be obvious that the same may be varied in many ways. Such variations are not to be regarded as a departure from the spirit and scope of the invention, and all such modifications as would be obvious to one skilled in the art are intended to be included within the scope of the following claims. 

What is claimed is:
 1. A cooling assembly for an engine, the engine including first and second cylinder blocks with respective cylinder bores extending in a direction orthogonal to an axis of a crankshaft and arranged at right angles to the axis of the crankshaft, a first cooling jacket provided on the first cylinder block and a first cylinder head connected to the first cylinder block, a second cooling jacket provided on the second cylinder block and a second cylinder head connected to the second cylinder block, and a single water pump has first and second discharge ports respectively independently connected to the first and second cooling jackets, said cooling assembly comprising: a circular pump chamber for rotatably housing an impeller, said circular pump chamber being located inside a pump housing of the water pump, the water pump being arranged between the first and second cooling jackets at a position below a lowest part of the first and second cooling jackets; an upper discharge path extending in a diagonally upwards direction and connecting to an upper end section of the pump chamber; a lower discharge path extending in a diagonally downwards direction and connecting to a lower end section of the pump chamber; and first and second connecting pipes respectively extending in a straight line along a line extended from the upper and lower discharge paths in said diagonally upwards direction and said diagonally downwards direction, respectively, said first and second connecting pipes having inner ends communicating with the upper and lower discharge paths and outer ends forming the first and second discharge ports of the water pump.
 2. The cooling assembly for an engine as disclosed in claim 1, wherein first and second inlet pipes are respectively connected between the first discharge port and the first cooling jacket, and between the second discharge port and the second cooling jacket, and the length of the first inlet pipe is shorter than the length of the second inlet pipe by a distance causing a flow resistance corresponding to a difference in height between the first and second discharge ports on the second inlet pipe side.
 3. The cooling assembly for an engine as disclosed in claim 1, wherein said pump housing further comprises a pump body rotatably supporting a pump shaft, and a pump cover connected to the pump body, said pump cover covering the impeller, said impeller being fixed to the pump shaft.
 4. The cooling assembly for an engine as disclosed in claim 3, wherein the pump body is connected to an outer surface of a front case half of a crankcase of the engine, and a cylindrical support pipe section provided integrally with the pump body is air-tightly fit inside the front case half.
 5. The cooling assembly for an engine as disclosed in claim 4, wherein the pump cover is connected to the pump body to form said circular pump chamber, the circular pump chamber being coaxial to the pump shaft and located between the pump cover and the pump body.
 6. The cooling assembly for an engine as disclosed in claim 5, wherein the pump shaft has a first end inserted into the pump chamber and a second end rotatably supported by the cylindrical pipe section in a fluid tight manner, the impeller being arranged inside the pump chamber and fixed to said first end of the pump shaft.
 7. The cooling assembly for an engine as disclosed in claim 6, wherein first and second intake ports are in communication with the pump chamber, said first and second intake ports being provided in the pump cover, and the first intake port is for connecting to a thermostat of the engine and the second intake port is for connecting to a radiator of the engine.
 8. An engine, comprising: first and second cylinder blocks with respective cylinder bores extending in a direction orthogonal to an axis of a crankshaft and arranged at right angles to the axis of the crankshaft; a first cooling jacket provided on the first cylinder block and a first cylinder head connected to the first cylinder block; a second cooling jacket provided on the second cylinder block and a second cylinder head connected to the second cylinder block; a single water pump having first and second discharge ports respectively independently connected to the first and second cooling jackets; a circular pump chamber rotatably housing an impeller, said circular pump chamber being located inside a pump housing of the water pump, the water pump being arranged between the first and second cooling jackets at a position below a lowest part of the first and second cooling jackets; an upper discharge path extending in a diagonally upwards direction and connecting to an upper end section of the pump chamber; a lower discharge path extending in a diagonally downwards direction and connecting to a lower end section of the pump chamber; and first and second connecting pipes respectively extending in a straight line along a line extended from the upper and lower discharge paths in said diagonally upwards direction and said diagonally downwards direction, respectively, said first and second connecting pipes having inner ends communicating with the upper and lower discharge paths and outer ends forming the first and second discharge ports of the water pump.
 9. The engine as disclosed in claim 8, wherein first and second inlet pipes are respectively connected between the first discharge port and the first cooling jacket, and between the second discharge port and the second cooling jacket, and the length of the first inlet pipe is shorter than the length of the second inlet pipe by a distance causing a flow resistance corresponding to a difference in height between the first and second discharge ports on the second inlet pipe side.
 10. The engine as disclosed in claim 8, wherein said pump housing further comprises a pump body rotatably supporting a pump shaft, and a pump cover connected to the pump body, said pump cover covering the impeller, the impeller being fixed to the pump shaft.
 11. The engine as disclosed in claim 10, wherein the pump body is connected to an outer surface of a front case half of a crankcase, and a cylindrical support pipe section provided integrally with the pump body is air-tightly fit inside the front case half.
 12. The engine as disclosed in claim 11, wherein the pump cover is connected to the pump body to form said circular pump chamber, the circular pump chamber being coaxial to the pump shaft and located between the pump cover and the pump body.
 13. The an engine as disclosed in claim 12, wherein the pump shaft has a first end inserted into the pump chamber and a second end rotatably supported by the cylindrical pipe section in a fluid tight manner, the impeller being arranged inside the pump chamber and fixed to said first end of the pump shaft.
 14. The engine as disclosed in claim 13, wherein first and second intake ports are in communication with the pump chamber, said first and second intake ports being provided in the pump cover, and the first intake port is connected to a thermostat and the second intake port is connected to a radiator. 